KR100998558B1 - Robot controller bootloader monitoring apparatus - Google Patents

Abstract

The robot controller boot loader monitoring apparatus according to the present invention connects to the boot loader of the robot controller through connection-oriented socket communication, and performs a function of a boot command and a data exchange function consisting of a system management command, a memory management command, or an application program management command. A connection-oriented communication interface that provides a connection-oriented communication interface that provides a communication function with a boot loader of the robot controller before being connected to the boot loader of the robot controller through a connection-oriented communication interface. It is characterized by determining the state of the robot controller using the information transmitted and received through.

Boot Loader, Robot Controller, TCP, UDP

Description

ROBOT CONTROLLER BOOTLOADER MONITORING APPARATUS}

The present invention relates to a robot controller boot loader monitoring apparatus for monitoring an operation state of a robot controller using a connectionless connection-oriented communication method and a connection-oriented communication method.

In general, the robot is equipped with a built-in robot controller for controlling the movement and operation of the robot. Such a robot controller may be classified into a controller to which a separate operating system and a file system are applied and a controller independently developed as needed without an operating system and a file system.

In addition, the embedded robot controller is equipped with a memory that can store a variety of applications for controlling the operation and movement of the robot.

The operating system and file system are applied to the memory in the embedded robot controller, and various robot-related application programs are loaded to control the operation of the robot.

In order to monitor the operation state of the robot controller, the boot loader and the monitoring device in the robot controller must be connected. Generally, the boot loader and the monitoring device are connected by using a short range communication interface, such as RS-232C or USB. Monitor the operating status.

However, the monitoring method of the robot controller using the short range communication interface is limited in the management and operation of the monitoring system because only the robot controller in the short range can be monitored due to the communication distance limitation.

The present invention connects a boot loader for a robot controller and a monitoring device by using a connectionless communication interface and a connection-oriented communication interface to remotely monitor a remote robot controller and to simultaneously monitor a plurality of robot controllers. .

As a first aspect of the present invention, the robot controller boot loader monitoring apparatus is a boot loader monitoring apparatus for loading and executing an application program and monitoring the operation of the robot controller, and is connected to the boot loader of the robot controller through connection-oriented socket communication. A connection-oriented communication interface that provides a boot command function and a data exchange function consisting of a system management command, a memory management command, or an application management command, and before being connected to the boot loader of the robot controller through the connection-oriented communication interface. And a connectionless oriented communication interface providing a communication function with a boot loader of the robot controller, wherein the bootloader monitoring apparatus determines a state of the robot controller by using information transmitted and received through the connectionless oriented communication interface. Characterized by .

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The present invention checks the operation state of the robot controller using a connectionless communication interface, and provides a boot command and a file transfer function using the connection-oriented communication interface, thereby managing a plurality of robot controllers using one host terminal. In addition to being able to do so, it has the effect of monitoring a remote robot controller.

In addition, the present invention by checking the operating state of the robot controller using a connection-oriented communication interface, there is an effect that can recognize the operating state of the robot controller without a login process.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. In addition, in describing the present invention, when it is determined that the detailed description of the related known configuration or function may obscure the gist of the present invention, the detailed description thereof will be omitted.

According to a preferred embodiment of the present invention, a boot loader for monitoring and a boot loader for a robot controller, which not only can change hardware configuration and system configuration of a robot controller through a communication interface or load and execute an application program, but also provide a monitoring function. Explain.

1 is a block diagram illustrating a boot loader and a device for monitoring the robot controller according to the present invention, which includes a boot loader monitoring apparatus 100 and an embedded robot controller boot loader 150. The bootloader monitoring apparatus 100 includes a first communication interface 102, a boot command interface 104, a data management layer 106, and a display layer 108, and the bootloader 150 for a robot controller includes a second The communication interface 152, the boot command interpreter 154, the SRAM management unit 156, the flash management unit 158, the hardware management unit 160, the setting information management unit 162, and the application program management unit 164.

The boot loader monitoring apparatus 100 connects to the boot controller 150 for the robot controller to change the setting information 162 or load and execute an arbitrary application program to monitor the operation of the robot controller. That is, the bootloader monitoring apparatus 100 receives information from the bootloader 150 for robot controllers through a connectionless connection-oriented communication interface, for example, UDP socket communication, and monitors a state of the robot controller. The boot command and file transfer data are exchanged with the robot controller boot loader 150 through TCP socket communication.

The first communication interface 102 provides UDP socket communication, which is a connectionless-oriented communication interface for providing a boot loader monitoring function of the boot loader monitoring apparatus 100, and the boot loader 150 for the robot controller and boot commands and files. Provides TCP socket communication, a connection-oriented communication interface for transport.

The boot command interface 104 transmits a command to the robot controller boot loader 150 through the first communication interface 102, extracts data from the response of the robot controller boot loader 150 to the command, and manages data. Pass to layer 106.

The data management layer 106 extracts the robot controller related information from the data provided from the boot command interface 104 and then manages the collected information.

The display layer 108 is a means for displaying the robot controller-related information managed in the data management layer 106, and a configuration view for displaying hardware configuration, system setting, boot loader setting information, and the like among the robot controller-related information. ), SRAM view showing the contents of the SRAM that is the volatile memory of the robot controller boot loader 150, Flash view and the robot that displays the summary information and contents of the nonvolatile memory of the boot loader 150 for the robot controller It includes an APP view that displays summary information and stored contents of an application program stored in the controller boot loader 150.

The bootloader 150 for the robot controller manages the setting information 162 of the robot controller and communicates with the first communication interface 102 of the bootloader monitoring apparatus 100 through the second communication interface 152. The application program may be loaded and executed according to the boot command, or the configuration information 162 may be extracted and provided to the boot loader monitoring apparatus 100. To this end, the second communication interface 152 of the bootloader 150 for the robot controller uses a UDP socket for supporting connectionless communication with the bootloader monitoring apparatus 100 and a TCP socket for supporting connection-oriented communication. Equipped.

That is, the second communication interface 152 is a UDP socket and a boot command, which is a connectionless-oriented communication interface for providing the boot loader monitoring apparatus 100 with information for boot loader monitoring before being connected to the boot loader monitoring apparatus 100. After receiving the transmission and transmits a response corresponding thereto, it comprises a TCP socket which is a connection-oriented communication interface for file transfer. Here, the connection-oriented communication interface provides a boot command function and a data exchange function with an external device, that is, the boot loader monitoring device 100, and the connectionless communication interface provides a boot message along with booting of the boot loader 150 for the robot controller. It provides a function of broadcasting or receiving information broadcast on the network.

The boot command interpreter 154 provides a function of receiving a boot command received from the second communication interface 152 and interpreting and responding to the boot command.

The SRAM management unit 156 analyzes and manages the SRAM usage history, which is the volatile memory of the robot controller, and the Flash management unit 158 analyzes and manages the usage history of the flash memory, which is the nonvolatile memory of the robot controller.

The hardware manager 160 analyzes and manages hardware of the robot controller boot loader 150, and the configuration information manager 162 includes hardware configuration information, system configuration information, boot loader configuration information, application program configuration information, and the like of the robot controller. Manage it.

The application manager 164 stores and manages up to N robot applications according to the hardware specifications of the robot controller.

The bootloader monitoring apparatus 100 having the above configuration receives the boot command for controlling the bootloader 150 for the robot controller before logging in using the connectionless-oriented communication interface of the first communication interface 102. When it is impossible to receive information to determine the state of the robot controller. That is, the boot loader 150 for the robot controller broadcasts a boot message through the UDP socket which is a connectionless interface of the second communication interface 150 as the robot controller is booted, and accordingly, the boot loader monitoring apparatus 100 Receives a boot message through the UDP socket of the first communication interface 102, allowing the user to recognize that the robot controller has booted. Thus, the user connects to the robot controller boot loader 150 through a login command of the boot loader monitoring apparatus 100.

In addition, the boot loader monitoring apparatus 100 broadcasts an arbitrary command, for example, a WHOIS command, to the network through UDP socket communication, which is a connectionless communication interface of the first communication interface 102, thereby operating a robot controller normally operating on the network. You can search for.

Meanwhile, the boot controller 150 for the robot controller operates as a socket server by activating a TCP socket port for a boot command, which is a connection-oriented communication interface of the second communication interface 152 at the same time as booting. At this time, the robot controller boot loader 150 provides only one boot command port as a socket server to allow only one client, that is, the connection of the boot loader monitoring apparatus 100. That is, if any boot loader monitoring apparatus 100 is connected to the boot loader 150 for robot controllers, the socket connection request of another boot loader monitoring apparatus 100 on the network is rejected.

As such, the boot command transmitted and received via the connection-oriented communication interface of the robot controller boot loader 150 operates as a client-server, a command request and response structure, and also supports remote access through an external communication network such as the Internet.

As a boot command, as shown in FIG. 2, a system management command, a memory management command, an application program management command, etc. are mentioned.

In addition, since the boot command provides each function as an ASCII communication based boot command and subsequent parameters are determined according to the command, the boot command is determined by the command syntax between the boot command interpreter 154 and the boot command interface 104 without any protocol. Each function can be provided, so each function can be easily implemented and extended.

The boot controller 150 for the robot controller activates a TCP socket for file transfer, which is a connection-oriented communication interface of the second communication interface 152, and operates as a socket server. The file transfer function using the TCP socket is provided through a separate data transfer protocol consisting of "DaraTransferInit", "DataTransfer" and "DataTransferAckNak" services, as shown in FIG.

A method of monitoring a plurality of robot controllers using the boot loader monitoring apparatus as described above will be described with reference to FIG. 4.

As shown in FIG. 4, the host terminal 400 including the plurality of boot loader monitoring apparatuses 100/1, 100/2,..., 100 / n includes a network device 410, for example, a hub HUB. A plurality of first, second, and third robot controllers 420/1, 420/2, and 420/3 are connected to each other. In this case, the third robot controller 420/3 is connected through the Internet 430, and the first and second robot controllers 420/1, 420/2, and 420/3 include an application program and a boot loader. It is.

The first, second, and third robot controllers 420/1, 420/2, and 420/3 generate a boot message when booted, and then generate the boot message to the host terminal 400 through a connectionless communication interface, for example, UDP socket communication. The host terminal 400 may recognize the booting state of the first, second, and third robot controllers 420/1, 420/2, and 420/3 based on the boot message.

In addition, the first, second and third robot controllers 420/1, 420/2 and 420/3 and the boot loader monitoring devices 100/1, 100/2, ..., 100 / n in the host terminal 400 Executes the boot command function and the file transfer function via a connection-oriented communication interface, such as TCP socket communication. At this time, one boot loader monitoring apparatus monitors and manages one robot controller.

According to the present invention, the state of the robot controller is determined through the connectionless communication interface, and the file transfer and boot command functions with the robot controller are executed by using the connection-oriented communication interface, so that the state of the robot controller can be determined without a login process. Can be.

The present invention has been limited to the preferred embodiment of the present invention, but it is obvious that the technology of the present invention can be easily modified by those skilled in the art. Such modified embodiments should be included in the technical spirit described in the claims of the present invention.

1 is a block diagram showing a boot loader of the robot controller and an apparatus for monitoring the same according to the present invention,

2 is a diagram illustrating the types and functions of boot commands applied to the present invention.

3 is a diagram illustrating a file transfer protocol applied to the present invention.

4 is an exemplary view showing an example in which the monitoring apparatus according to the present invention is applied on a network.

Description of the Related Art

100: boot loader monitoring apparatus 102: first communication interface

104: boot command interface 106: data management layer

108: display layer 150: boot loader for the robot controller

152: second communication interface 154: boot command interpreter

156: SRAM management unit 158: Flash management unit

160: hardware management unit 162: setting information management unit

168: Application Management Department

Claims (11)

delete delete delete delete A bootloader monitoring device that loads and executes applications and monitors the operation of the robot controller. A connection-oriented communication interface that connects to the boot loader of the robot controller through connection-oriented socket communication and provides a function of a boot command and a data exchange function consisting of a system management command, a memory management command, or an application management command; A connectionless oriented communication interface providing a communication function with a boot loader of the robot controller before being connected to the boot loader of the robot controller through the connection oriented communication interface, And the boot loader monitoring apparatus determines the state of the robot controller using information transmitted and received through the connectionless communication interface. The method of claim 5, The connection-oriented communication interface, A boot socket TCP for transmitting the boot command to a boot loader of the robot controller and receiving a response corresponding to the boot command; TCP socket for file transfer for exchanging data with the boot loader of the robot controller Robot controller boot loader monitoring device comprising a. delete The method of claim 5, The boot loader monitoring apparatus checks an operation state of a boot loader of the robot controller connected to the network by broadcasting a predetermined command on the network through the connectionless communication interface. monitor. The method of claim 8, The connectionless connection-oriented communication interface is a robot controller boot loader monitoring device, characterized in that the UDP socket communication. The method of claim 5, The boot loader monitoring device, A boot command interface for transmitting a command to the robot controller boot loader through the connectionless communication interface and the connection-oriented communication interface, and extracting data from a response to the transmitted command from the robot controller bootloader; A data management layer that manages the robot controller related information from data extracted from the boot command interface; Display layer for displaying information managed in the data management layer Robot controller boot loader monitoring device further comprising. The method of claim 10, The display layer is, A first view displaying at least one of hardware configuration, system configuration, and boot loader configuration information of the robot controller; A second view for displaying data information stored in a volatile memory of the robot controller; A third view displaying data information stored in a nonvolatile memory of the robot controller; A fourth view displaying information and stored contents of an application program stored in the boot loader among the robot controller related information; Robot controller boot loader monitoring device comprising a.

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